SU1048326A2 - Rotation-type gas meter and gas consumption meter graduation and checking device - Google Patents

Abstract

1. DEVICE FOR GRADING AND TESTING OF POTAIWOHHUX COUNTERS AND GAS FLOW METERS St. 609972, characterized in that, in order to increase the reproducibility of the gas flow rate and the efficiency of using the bell volume and expand the measuring range towards high flow rates, the annular tank is equipped with a means of communication-barrier fluid of circumferential speed relative to its vertical axis. .. 2. The device according to claim 1, wherein the means for communicating the barrier fluid of peripheral speed is made in the form of pressure and receiving nozzles located on the inner and external walls of the ring reservoir along its height and connected to them by means of pressure and receiving pipelines of the pump.

Description

 S p The invention relates to a measuring technique, can be used in measuring devices used in the calibration and calibration of gas meters and flow meters. According to the main author. St. No. 609972, a device for calibration and calibration of rotary meters and gas flow meters is known, which is used mainly in the calibration and calibration of gas meters and flow meters. This device is made in the form of a bell immersed in an annular reservoir with liquid and contains a gas feed, a piping system with shut-off members, electronic devices for reading the readings of the device under test, and a frame with a gearbox mounted on it and an electric rotation of the bell. In this device, in order to improve the sensitivity and accuracy, as well as to expand the lower limit of the measurement, the bell is shown to rotate around the vertical axis.;. The device most effectively provides an increase in the accuracy of measurement during calibration and calibration of instruments with automatic removal on the move at low costs. When testing devices at high flow rates, the angular velocity of the bell 1 should be significantly increased. However, it is almost impossible to report the bell to a significant angular velocity due to the inevitable deviations of its walls from a strictly cylindrical shape and the presence of imbalance and radial beats. This would lead to a breach of its stability and unacceptable oscillations of the test device. In addition, when high gas flow rates are reproduced, the accuracy of the device increases slightly due to the high speed of lowering the bell and increasing the force of frontal resistance to its movement, which, in turn, worsens the stability of the pressure under the bell and the flow rate. Moreover, the rotational movement of the bell can reduce the force of frontal resistance to its movement also at high speeds, but the positive effect in this case is not so significant. In turn, a decrease in the speed of lowering the bell leads to a decrease in the upper limit of measurement of the device for calibration and calibration of rotary meters and gas flow meters. The increase in the force of frontal resistance to the movement of the bell is especially noticeable when the bell end approaches the bottom of the annular tank. This limits the progress of the bell and, as a result, leads to a decrease in the efficiency of its use. On the other hand, if you do not change the bell stroke, then with an increase in the minimum distance from its end in the lowest position to the bottom of the tank, it is necessary to increase the height of the annular tank with liquid, which leads to an increase in the overall dimensions of the device for calibration and calibration of gas meters and flow meters generally. The purpose of the photogrid is to increase the accuracy of reproducing the gas flow rate and the efficiency of using the bell volume, and to expand the measuring range towards high flow rates. This goal is achieved. In the device for calibration and calibration of rotary meters and gas flow meters, the annular tank is provided with a means of communicating the barrier fluid of peripheral velocity relative to its vertical axis. The tool is made in the form located on the inner and outer walls of the annular reservoir, evenly. its height of pressure and receiving nozzles and connected to them with the help of pressure and receiving pipelines of the pump. FIG. 1 shows a device for calibration and verification of rotational counters and gas flow meters in FIG. 2 is an annular reservoir, section A-A in FIG. 1. The device for calibration and verification of gas meters and flowmeters consists of a bell 1 immersed in an annular tank 2 with a liquid, a gas feeder 3, a pipeline 4 and 5 with valves 6 and 7, a frame 8 with a gear 9 installed above and an electric drive 10 rotation of the bell and reading devices 11 for carrying out the readings of the test device 12 on the go. The device contains means for communicating the barrier liquid of circumferential speed relative to the vertical axis of the bell, made, for example, in the form of evenly spaced 2 are annular reservoir pressure 13, 13 and receiving 15, 16 of nozzles arranged on the inner and outer tank walls. Nozzles 13-16 are connected to the pump 17 by means of receiving 18 and pressure 19 pipelines. During the calibration or calibration of the device 12 when it is read off, the bell 1 goes down and displaces the gas volume measured by the reading devices 11. Comparing the readings of the device 12 with the flow rate or amount

gas, measured using a sample device, judged on the accuracy of the gas meters and flow meters under test. ,

When lowering the bell 1 with the help of the electric drive 10 and the gearbox 9,. mounted on frame 8, the bell is said to rotate around a vertical axis. Simultaneously, the barrier fluid in the annular reservoir is said to have a circular velocity. This is achieved by forcibly circulating the barrier fluid successively through the receiving nozzles 15 and 16, the pipeline 18, the pump 17, the pipeline 19, the pressure nozzles 13 and 14, and further around the circumference of the annular tank to the receiving nozzles 15 and 16.

Pressure nozzles 13 and 14 are interconnected in parallel and are placed, for example, in pockets located on the walls of the annular tank. The device ensures that the maximum circumferential velocity of the liquid under the end surface of the colo is achieved without increasing the width of the annular tank 2. In this case, the location of the nozzles relative to the walls of the tank is calculated depending on its geometrical dimensions.

When calculating them, they are based on the condition of achieving equality and minimality of the angles formed by the intersection of the axes of the pressure nozzles 13 and 14 and the straight line drawn from the intersection point of the indicated axes in the direction of the nozzles (Fig. 2). In this case, the point of intersection of the nozzle axes should be on the circle formed by the average radius of the GSR of the inner and outer walls of the bell, and the straight line drawn between the nozzle axes from the point of their intersection should be tangent to the radius circle. Thus, the equality and minimality of the angles oL and ci.2 are characteristic parameters of the proposed device which ensure the achievement of the maximum circumferential velocity of the liquid under the end edge of the walls of the rotating bell.

The receiving nozzles 15 and 16 are interconnected in parallel and are also placed, for example, in pockets located on the walls of the annular tank 2.

To ensure maximum efficiency of fluid communication, the rotational motion in the annular tank and the constancy of the fluid velocity over its height are both pressure and

reception1: .1e are connected in parallel. At the same time, pressure and receiving nozzles, should be at a minimum distance, which prevents the direct ingress of liquid from the pressure nozzles into the receiving nozzles, the flow along the circumference along the walls of the annular tank.

Providing the circumferential speed of the sealing liquid in the annular reservoir, along with the rotation of the bell, makes it possible to reduce the force of drag on the displacement of the bell. This improves (.1 pressure stability under the colo OM, and therefore increases the stability of the gas flow rates reproduced by the device. In turn, this is npHH.:,iiii to improve the accuracy of the calibration device.

Reducing the drag force also makes it possible to increase the speed of lowering the bell without impairing the accuracy of the device, thereby extending the measurement range to the side. high costs. In this case, it becomes possible, with a constant value of the permissible error of the device, to increase the bell, which leads to an increase in the efficiency of using its volume.

The effect of reducing the force of frontal resistance in the proposed device ..: can reach significantly larger gels; yna than in the known. In view of the proliferation of the valve, the possibility of communicating the sealing liquid is much greater than the circumferential speed as compared with the circumferential velocity of the rotating wall of the rotating bell. In addition, the reduction of the lobovog force is influenced both by the angle; :: o; the rotation of the bell and the value the peripheral velocity of the barrier fluid in the annular massif. Increasing each of these velocities leads to an increase in the effect obtained.

Studies have shown that the error in reproducing a stable gas flow rate in such a device with a bell with a volume of 5 m when the bell is rotated at a speed of 0.25 rev / s and the fluid in the annular reservoir at a speed of 0.75 rev / s decreases by about 0 ,, and the utilization efficiency of the colocoine increases by 3%. At the same time, the expansion of the measurement range towards higher costs is 5%, which is very significant for a sample device.

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Claims (2)

1. DEVICE FOR GRADING AND VERIFICATION OF ROTARY METERS AND GAS FLOW METERS BY AUT. St. No. 609972, characterized in that, in order to increase the accuracy * 6 of reproducing the gas flow rate and the efficiency of using the volume of the bell and expanding the measuring range towards higher flow rates, the annular tank is equipped with a means of communicating ’the shutter fluid of peripheral speed relative to its vertical axis. 2. The device pop. 1 t of whether sistent in that the means of communicating buffer fluid circumferential speed is in the form arranged on the inner and outer annular walls of the tank along its height and pressure receiving nozzles and connected thereto via _a pressure pump and receive pipelines. 3 .... 1048326